Production of neutral and alkaline proteases in batch and chemostat cultures by bacillus mesentericus 76

The kinetics of the bacterial extracellular protease synthesis (neutral and alkaline protease of Bacillus mesentericusstrain 76, R-form) in batch and chemostat cultures under conditions of glucose limitation were investigated. When the medium was supplemented with casein the production of the proteases was significantly higher. Optimal dilution rates for obtaining of two proteases are fixed. The synthesis of both alkaline and neutral proteases is controlled by catabolite repression and induction.     

Preparation and Purification of Microbial Proteases With Special Reference to The Bacilli

Methods for the examination of bacteria for protease production on semisolid media are described. The selection of media for production of small quantities of crude bacterial proteases from pure cultures of selected microorganisms in shake flasks is discussed. The most useful media have been found to be a grain-based medium, a soya fluff-starch-yeast extract medium and a fish meal-enzose-cerelose-cornsteep liquor medium. The alkaline proteases and neutral proteases can be identified and differentiated by specific assays and a purification procedure planned dependent upon the enzymes present in the fermentation beer. Crude enzyme can be precipitated from the fermentation beer by the addition of organic solvents such as acetone or isopropanol or by the addition of salts such as ammonium or sodium sulfate. The alkaline proteases typified by B. subtilis alkaline protease can be extensively purified by chromatography on Duolite C-10 cation exchange resin, whereas the neutral protease of 3 subtilis is best purified by chromatography on hydroxylapatite. Methods for purification of other proteases are discussed and the prechromatography steps for removal of pigment and other gross impurities are described.     

Cloning of the gene responsible for the extracellular proteolytic activities of Bacillus licheniformis

Summary Effect of the cloned gene of Bacillus licheniformis on the extracellular proteolytic activities of B. subtilis was investigated. The gene was cloned onto the vector plasmid pUB110 (3.0 Md), and the introduction of the hybrid plasmid [pAN2 (5.4 Md)] into the cells of B. subtilis resulted in a marked increase of activities of the extracellular alkaline and neutral proteases, which had optimal pHs at 10.5 and 7.2, respectively. On DEAE-Sephadex column chromatography, the extracellular activity of B. subtilis with pAN2 was separated into two active fractions (a₁ and b₁). The activity in a₁ was specifically inactivated by diisopropyl phosphorofluoridate (DFP) and tosyl fluoride (TSF), potent inhibitors of alkaline proteases, while, the activitiy in b₁ was inhibited by ethylenediaminetetraacetate (EDTA), an inhibitor of neutral protease, but not by DEP or TSF.Sub-cloning with genes shortened to about 0.85 Md (pAN2-1) and 0.25 Md (pAN2-2) increased the activities of both alkaline and neutral proteases. The extracellular -amylase and ribonuclease production was also increased when the host strain was transformed with these hybrid plasmids (pAN2, pAN2-1, pAN2-2). The increase in activity of proteases by the cloning was discussed in relation to regulation of the production and/or secretion of the enzyme.     

Studies on the Protease Constitution of Aspergillus oryzae

In order to elucidate the protease constitution of Aspergillus oryzae, systematic separation of proteases was elaborated by sequential chromatography on Amberlite CG–50, DEAE-Sephadex A–50 and CM-cellulose. As the results, three kinds of proteases, that is, acid-, neutral- and alkaline proteases were isolated and purified in crystalline form except neutral one. Purified neutral protease could not be crystallized, but was confirmed to be homogeneous by ultracentrifugal analysis. Besides these proteases, a new protease which was unknown up to the present in the constitution of Asp. oryzae proteases, was first isolated and designated as “semi-alkaline protease” according to its optimal pH.     

Stabilization of proteolytic enzymes in solution

The stability of the neutral and alkaline proteases in a Bacillus subtilis enzyme mixture was studied in aqueous solutions at room temperature. Stabilization of the proteases in solution for periods up to 25 days was achieved by the addition of various protein preparations including casein and soya protein. The degree of stabilization by casein was concentration dependent to about 2% protein. The instability of the neutral protease in solutions of the B. subtilis enzyme mixture was shown to be due primarily to proteolysis by the alkaline protease since the diisopropylfluorophosphate-treated enzyme was quite stable. Formulation of such enzyme solutions at low pH gave greater stability as did solutions containing an alkaline protease inhibitor from potatoes. A Conceptual approach to the formulation of enzyme solutions containing proteolytic enzyme to ensure maximum stability is proposed.     

Regulation of Neutral Protease Productivity in Bacillus subtilis: Transformation of High Protease Productivity

A transformable strain of Bacillus subtilis 6160, a derivative of B. subtilis 168, produces three kinds of casein hydrolytic enzymes (alkaline protease, neutral protease, and esterase) in a culture medium. B. natto IAM 1212 produces 15 to 20 times as much total proteolytic activity as does B. subtilis. Extracellular proteases produced by the two strains were separated into each enzyme fraction by diethylaminoethyl-Sephadex A-50 column chromatography. The difference in the total protease activities of extracellular proteases between the two strains was due to the amount of neutral protease. The ratios of neutral protease activity to alkaline protease activity (N/A) were 1.1 in B. subtilis 6160 and 13.0 in B. natto IAM 1212. Enzymological and immunological properties of alkaline protease and neutral protease obtained from the two strains were quite similar or identical, respectively. Specific activities measured by an immunological analysis of the two neutral proteases against casein were also equal. A genetic character of high protease productivity in B. natto IAM 1212 was transferred to B. subtilis 6160 by the deoxyribonucleic acid-mediated transformation. Among 73 transformants that acquired high protease productivity, 69 produced a higher amount of neutral protease and the ratios of N/A were changed to 15 to 60. Three other strains were transformed in the productivity of neutral protease and alpha-amylase simultaneously, and one showed considerable change in the production of alkaline protease and neutral protease. The specific activities (casein hydrolytic activities/enzyme molecules) of neutral proteases from the representative four transformants were equal to those of the two parental strains. These results suggested the presence of a specific gene(s) that participated in the productivity of neutral protease in B. subtilis.     

Calcium requirements of residual protease in Bacillus subtilis DB104

Summary Bacillus subtilis DB104, a double mutant which does not synthesize neutral or alkaline proteases, was shown to exhibit some residual proteolytic activity when grown in both batch and continuous cultures. A major protein component responsible for about 70% of extracellular residual protease activity was reversibly deactivated by removal of calcium.     

Proteases of the genus Bacillus. II. Alkaline proteases

The alkaline proteases of B. subtilis NRRL B3411, B. pumilis, and B. licheniformis have been isolated by fractionation followed by ion exchange chromatography and their homogeneity demonstrated. General enzyme properties of the B. sublitis NRRL B3411 alkaline protease have been studied and attempts made to differentiate a group of alkaline proteases. It is clear that the alkaline proteases known as Subtilisins or Subtilopeptidases are not, exclusive to B. subtilis but are common to many Bacilli and therefore the generic name Bacillopeptidases has been proposed. It is clear too that on the basis of the effect of pH on activity, amino acid composition, esterase activity, and immunological cross-reactions the Bacillopeptidases can be divided into two groups or types: (a) Bacillopcptidase A (Subtilisin A or Subtilopeptidase A) which includes Subtilisin Carlsberg, B. licheniformis, and B. pumilis alkaline proteases; ( b ) Bacillopeptidase B (Subtilisin B or Subtilopeptidase B) which includes B subtilis NRRL B3411, Subtilisin Novo, Subtilisin BPN' (Nagarse), alkaline protease Daiwa Kasei, and (probably) B. subtilis var. amylosacchariticus. At present, no further differentiation is possible and whether or not the enzymes within group A or B are identical remains an open question. Methods for examination of crude enzyme mixtures or fermentation beers are described and from the examination of a number of crude enzymes and fermentation beers it appears that organisms producing Bacillopeptidase A do not produce neutral protease or amylase, while organisms producing Bacillopeptidase B produce a neutral protease and amylase as well.     

Properties of extremely thermostable proteases from anaerobic hyperthermophilic bacteria

Summary Hyperthermostable proteases were characterized from five archaeobacterial species (Thermococcus celer, T. stetteri, Thermococcus strain AN 1, T. litoralis, Staphylothermus marinus) and the hyperthermophilic eubacterium Thermobacteroides proteolyticus. These proteases, which were found to be of the serine type, exhibited a preference for phenylalanine in the carboxylic side of the peptide. The enzymes from Thermococcus stetteri and T. litoralis hydrolysed most substrates (peptides) tested. All proteases were extremely thermostable and demonstrated optimal activities between 80 and 95°C. The pH optimum was either neutral (T. celer, Thermococcus strain AN 1) or alkaline. The protease of Thermobacteroides proteolyticus was optimally active at pH 9.5. Zymogram staining showed the presence of multiple protease bands for all strains investigated.Offprint requests to: G. Antranikian     

Preparation and properties of proteases immobilized on anion exchange resin with glutaraldehyde

High activity alkaline protease was obtained when the enzyme was immobilized on Dowex MWA-1 (mesh 20–50) with 10% glutaraldehyde in chilled phosphate buffer (M/15, pH 6.5). Activity yields of the protease and rennet were 27 and 29, respectively. The highest activities appeared at 60°C, pH 10 for alkaline protease and 50°C, pH 4.0 for rennet. The properties of both proteases were not essentially changed by the immobilization except that the K_m values of both enzymes were increased about tenfold as a result of immobilization. Both proteases in the immobilized state were more stable than those in the free state at 60°C. Other peptide hydrolases, β-galactosidase, invertase, and glucoamylase, were successfully immobilized with high activities, but lipase, hexokinase, glucose-6-phosphate dehydrogenase, and xanthine oxidase became inactive.     

Molecular cloning,nucleotide sequence and expression of the structural gene for a thermostable alkaline protease from Bacillus sp. no. AH-101

Summary Alkaliphilic Bacillus sp. no. AH-101 produces an extremely thermostable alkaline serine protease that has a high optimum pH (pH 12–13) and shows keratinolytic activity. The gene encoding this protease was cloned in Escherichia coli and expressed in B. subtilis. The cloned protease was identical to the AH-101 protease in its optimum pH and thermostability at high alkaline pH. An open reading frame of 1083 bases, identified as the protease gene, was preceded by a putative Shine-Dalgarno sequence (AAAGGAGG) with a spacing of 11 bases. The deduced amino acid sequence revealed a pre-pro-peptide of 93 residues followed by the mature protease comprising 268 residues. AH-101 protease showed slightly higher homology to alkaline proteases from alkaliphilic bacilli (61.2% and 65.3%) than to those from neutrophilic bacilli (54.9–56.7%). Also AH-101 protease and other proteases from alkaliphilic bacilli shared common amino acid changes and a four amino acid deletion when compared to the proteases from neutrophilic bacilli. AH-101 protease, however, was distinct among the proteases from alkaliphilic bacilli in showing the lowest homology to the others.Correspondence to: H. Takami     

海南近海水域产碱性蛋白酶菌株的分离筛选及发酵条件优化

【背景】微生物蛋白酶在工业生物技术上具有广阔的应用前景。在微生物蛋白酶中,碱性蛋白酶占全球酶总产量的50%以上,获取产碱性蛋白酶的新微生物资源意义重要。【目的】在海南近海贝类养殖基地海泥中筛选获得高产碱性蛋白酶的菌株,对其生长特性进行探究并优化菌株产酶条件,获得新的蛋白酶生产资源。【方法】以酪素培养基为筛选培养基,采用形态学结合系统发育分析鉴定菌株,通过响应面实验优化菌株的产酶条件。【结果】筛选获得一株高产碱性蛋白酶的菌株F3,鉴定为粘质沙雷氏菌（Serratia marcescens）。菌株在最优产酶条件下发酵酶活达到（339.36±4.30） U/mL。【结论】筛选获得的菌株粘质沙雷氏菌F3有较好的产碱性蛋白酶的能力。     

Extracellular and membrane-bound proteases from Bacillus subtilis.

Bacillus subtilis YY88 synthesizes increased amounts of extracellular and membrane-bound proteases. More than 99% of the extracellular protease activity is accounted for by an alkaline serine protease and a neutral metalloprotease. An esterase having low protease activity accounts for less than 1% of the secreted protease. These enzymes were purified to homogeneity. Molecular weights of approximately 28,500 and 39,500 were determined for the alkaline and neutral proteases, respectively. The esterase had a molecular weight of approximately 35,000. Amino-terminal amino acid sequences were determined, and the actions of a number of inhibitors were examined. Membrane vesicles contained bound forms of alkaline and neutral proteases and a group of previously undetected proteases (M proteases). Membrane-bound proteases were extracted with Triton X-100. Membrane-bound alkaline and neutral proteases were indistinguishable from the extracellular enzymes by the criteria of molecular weight, immunoprecipitation, and sensitivity to inhibitors. The M protease fraction accounted for approximately 7% of the total activity in Triton X-100 extracts of membrane vesicles. The M protease fraction was partially fractionated into four species (M1 through M4) by ion-exchange chromatography. Immunoprecipitation and sensitivity to inhibitors distinguished membrane-bound alkaline and neutral proteases from M proteases. In contrast to alkaline and neutral proteases, proteases M2 and M3 exhibited exopeptidase activity.     

Immunochemical characterization of commercial protease products

Total protease activity at pH 7 and 10.3 of 23 commercial grade enzymes was determined. The type and amount of enzymatic activity varied widely among the products. The wide variation in pH 7.0/pH 10.3 proteolytic activity ratios among products indicated that the products studied contained differing levels of alkaline and neutral proteases. Antisera were prepared against the purified enzyme in detergent grade Enzyme AP, neutral protease from B. megaterium, detergent grade ALK Enzyme, and Thermolysin. The commercial (unpurified) products were classified as neutral subtilopeptidase A and subtilopeptidase B from three Bacillus species using these antisera. It was concluded that standard immunochemical techniques provide rapid and sensitive methods for the preliminary identification of sources and types of proteases present in commercial enzyme products.     

Characterization of an alkaline serine protease from an alkaline-resistant Pseudomonas sp.: Cloning and expression of the protease gene in Escherichia coli

Summary A gene, aprP, encoding an extracellular alkaline serine protease from a newly isolated Pseudomonas sp. KFCC 10818 was cloned and characterized. Nucleotide sequence analysis revealed an open reading frame of 1,266 nucleotides which could encode a polypeptide comprised of 422 amino acids. The C-terminal 283 residues showed an overall sequence homology with the subtilisin-type serine proteases. When expressed in E. coli, the alkaline protease, AprP, was released to the culture medium. The purified AprP was most active at pH 11. The k _Cat/K _m value of this enzyme was 9.2 × 10³ S^–1mM^–1, which is much higher than those of subtilisins.     

Cloning,Characterization, and Expression of the Gene Encoding Alkaline Protease in the Marine Yeast <Emphasis Type="Italic">Aureobasidium pullulans</Emphasis> 10

The alkaline protease structural gene (ALP1 gene) was isolated from both the genomic DNA and cDNA of Aureobasidium pullulans 10 by inverse PCR and RT-PCR. An open reading frame of 1248 bp encoding a 415 amino-acid protein with calculated molecular weight of 42.9 kDa was characterized. The gene contained two introns, which had 54 bp and 50 bp, respectively. The promoter of ALP1 gene was located from -62 to -112 and had two CCAAT boxes and one TATA box. The terminator of ALP1gene contained the sequence with a hairpin structure (AAAAAGTT TGGTTTTT). The protein sequence deduced from ALP1 gene exhibited 55.24%, 50.35%, and 31.68% identity with alkaline proteases from Aspergillus fumigatus, Acremonium chrysogenum, and Yarrowia lipolytica, respectively. The protein was found to have the conserved serine active site and histidine active site of serine proteases in the subtilisin family. The recombinant A. pullulans alkaline protease produced in Y. lipolytica formed clear zones on the double plates with 2% casein and alkaline protease activity in the supernatant of the recombinant Y. lipolytica culture was detected, suggesting that the cloned ALP1 gene is expressed in Y. lipolytica and the expressed alkaline protease is secreted into the medium.     

Partial Purification of Mucor pusillus Intracellular Proteases

The intracellular protease extracted from the freeze-dried mycelia obtained after the growth of Mucor pusillus at 30°C in corn steep liquor medium was chromatographed on DEAE-A50. Some characteristics of the protease fractions obtained after ion-exchange chromatography were determined and compared with those of the extracellular proteases reported previously. The mycelia were found to contain two acid proteases and an alkaline protease. The ratio of milk clotting to protease activity of one acid protease was greater than that of the other. The electrophoretic pattern of the alkaline protease fraction suggested that it was not a single species, but a mixture of proteolytic enzymes.     

Characterization of proteolytic bacteria from the Aleutian deep-sea and their proteases

Six deep-sea proteolytic bacteria taken from Aleutian margin sediments were screened; one of them produced a cold-adapted neutral halophilic protease. These bacteria belong to Pseudoalteromonas spp., which were identified by the 16S rDNA sequence. Of the six proteases produced, two were neutral cold-adapted proteases that showed their optimal activity at pH 7–8 and at temperature close to 35°C, and the other four were alkaline proteases that showed their optimal activity at pH 9 and at temperature of 40–45°C. The neutral cold-adapted protease E1 showed its optimal activity at a sodium chloride concentration of 2 M, whereas the activity of the other five proteases decreased at elevated sodium chloride concentrations. Protease E1 was purified to electrophoretic homogeneity and its molecular mass was 34 kDa, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). The molecular weight of protease E1 was determined to be 32,411 Da by mass spectrometric analysis. Phenylmethyl sulfonylfluoride (PMSF) did not inhibit the activity of this protease, whereas it was partially inhibited by ethylenediaminetetra-acetic acid sodium salt (EDTA-Na). De novo amino acid sequencing proved protease E1 to be a novel protein.     

Secretion of Proteases from Pasteurella multocida Isolates

The capability of Pasteurella multocida to secrete proteases to the culture medium and their characterization were studied in five animal isolates (bovine, chicken, sheep, and two from pig). All the isolates produced proteases in a wide range of molecular mass. It is suggested that they are neutral metalloproteases, since they were optimally active between pH 6 and 7, inhibited by chelating agents but not by other protease inhibitors, and reactivated by calcium. Proteases from isolates were able to degrade IgG. Several proteins from supernatants of cultures precipitated with 70% (NH₄)₂SO₄ of all the P. multocida isolates were recognized by a polyclonal antiserum raised against a purified protease from Actinobacillus pleuropneumoniae. Protease production might play an important role during tissue colonization and in P. multocida diseases. Received: 26 May 1998 / Accepted: 15 August 1998     

Characterization of a novel cysteine peptidase from tissue culture of garlic (<Emphasis Type="Italic">Allium sativum</Emphasis> L.)

Summary A simple and efficient medium for callus tissue culture from garlic to obtain maximal proteolytic activity is described. Murashige and Skoog basal medium supplemented with 4.44 μM naphthaleneacetic acid (NAA) and 0.54 μM benzyladenine (BA) resulted in the best biomass production and protease expression. The protease activity belongs to the class of cysteine proteases since they are inhibited by E₆₄ and Leupeptin and also they are activated by 2-mercaptoethanol and cysteine. They showed good thermal stability. Three active protease bands were found in zymograms of Allium sativum. The in vitro system revealed a significantly higher protease level than storage and embryo tissues of in vivo bulbs.